M.E. de la Morena-Barrio

Regulatory regions of SERPINC1 gene: Identification of the first mutation associated with antithrombin deficiency

Antithrombin is the main endogenous anticoagulant. Impaired function or deficiency of this molecule significantly increases the risk of thrombosis. We studied the genetic variability of SERPINC1 , the gene encoding antithrombin, to identify mutations affecting regulatory regions with functional effect on its levels. We sequenced 15,375 bp of this gene, including the potential promoter region, in three groups of subjects: five healthy subjects with antithrombin levels in the lowest (75%) and highest (115%) ranges of our population, 14 patients with venous thrombosis and a moderate antithrombin deficiency as the single thrombophilic defect, and two families with type I antithrombin deficiency who had neither mutations affecting exons or flanking regions, nor gross gene deletions. Our study confirmed the low genetic variability of SERPINC1 , particularly in the coding region, and its minor influence in the heterogeneity of antithrombin levels. Interestingly, in one family, we identified a g.2143 C>G transversion, located 170 bp upstream from the translation initiation codon. This mutation affected one of the four regions located in the minimal promoter that have potential regulatory activity according to previous DNase footprinting protection assays. Genotype-phenotype analysis in the affected family and reporter analysis in different hepatic cell lines demonstrated that this mutation significantly impaired, although it did not abolish, the downstream transcription. Therefore, this is the first mutation affecting a regulatory region of the SERPINC1 gene associated with antithrombin deficiency. Our results strongly sustain the inclusion of the promoter region of SERPINC1 in the molecular analysis of patients with antithrombin deficiency.

Hypoglycosylation is a common finding in antithrombin deficiency in the absence of a SERPINC1 gene defect

Essentials We investigated the molecular base of antithrombin deficiency in cases without SERPINC1 defects. 27% of cases presented hypoglycosylation, transient in 62% and not restricted to antithrombin. Variations in genes involved in N‐glycosylation underline this phenotype. These results support a new form of thrombophilia.

Heparin affinity of factor VIIa: Implications on the physiological inhibition by antithrombin and clearance of recombinant factor VIIa

Factor VIIa (FVIIa), a trypsin-like serine protease, plays an essential role in haemostasis by initiating the coagulation in complex with its cofactor, tissue factor (TF). The TF pathway inhibitor is the main physiological inhibitor of FVIIa-TF complex, but FVIIa can also be inhibited by antithrombin, although little is known about this process. Functional analyses by second order kinetic determination and identification of FVIIa-antithrombin complex by electrophoresis, evaluating the effect of different cofactors: pentasaccharide, low molecular weight heparin (LMWH) and unfractionated heparin (UFH), confirmed that any activation of antithrombin significantly enhanced the inhibition of FVIIa. The analysis of the binding of FVIIa to heparin by surface plasmon resonance identified a high affinity interaction under physiologic conditions (K(D)=3.38 μM, with 0.15M of ionic strength) strongly dependent on Ca(2+) and ionic strength. This interaction was verified in cell models, indicating that FVIIa also binds to the surface of endothelial cells with similar requirements. Structural modeling suggests the presence of a potential exosite II in FVIIa. However, the binding of heparin did not display significant changes on both the intrinsic fluorescence and the associated functional consequences of FVIIa. These results indicate that FVIIa binds to exposed glycosaminglycans of the endothelium through an exosite II, structurally similar to that reported for thrombin and suggested for FIXa. This binding may favor its inhibition by antithrombin in the absence of TF, contributing to the physiological control of this protease. This process may also play an important role in the clearance of recombinant FVIIa administered to patients.

Antithrombin Dublin (p.Val30Glu): a relatively common variant with moderate thrombosis risk of causing transient antithrombin deficiency

The key haemostatic role of antithrombin and the risk of thrombosis associated with its deficiency support that the low incidence of antithrombin deficiency among patients with thrombosis might be explained by underestimation of this disorder. It was our aim to identify mutations in SERPINC1 causing transient antithrombin deficiency. SERPINC1 was sequenced in 214 cases with a positive test for antithrombin deficiency, including 67 with no deficiency in the sample delivered to our laboratory. The p.Val30Glu mutation (Antithrombin Dublin) was identified in five out of these 67 cases, as well as in three out of 127 cases with other SERPINC1 mutations. Genotyping in 1593 patients with venous thrombosis and 2592 controls from two populations, revealed a low prevalent polymorphism (0.3 %) that moderately increased the risk of venous thrombosis (OR: 2.9; 95 % CI: 1.07-8.09; p= 0.03) and identified one homozygous patient with an early thrombotic event. Carriers had normal anti-FXa activity, and plasma antithrombin was not sensitive to heat stress or proteolytic cleavage. Analysis of one sample with transient deficit revealed a type I deficiency, without aberrant or increased latent forms. The recombinant variant, which lacked the two amino-terminal residues, had reduced secretion from HEK-EBNA cells, formed hyperstable disulphide-linked polymers, and had negligible activity. In conclusion, p.Val30Glu by affecting the cleavage of antithrombins signal peptide, results in a mature protein lacking the N-terminal dipeptide with no functional consequences in normal conditions, but that increases the sensitivity to be folded intracellularly into polymers, facilitating transient antithrombin deficiency and the subsequent risk of thrombosis.

Role of the C-sheet in the maturation of N-glycans on antithrombin: functional relevance of pleiotropic mutations

The characterization of natural mutants identified in patients with antithrombin deficiency has helped to identify functional domains or regions of this key anticoagulant and the mechanisms involved in the deficiency, as well as to define the clinical prognosis. Recently, we described an abnormal glycosylation in a pleiotropic mutant (K241E) that explained the impaired heparin affinity and the mild risk of thrombosis in carriers.

Proteomic analysis of platelet N-glycoproteins in PMM2-CDG patients☆ , ☆☆

UNLABELLED PMM2-CDG, the most frequent congenital disorder of N-glycosylation, is an autosomal recessive disease with a multisystem presentation. PMM2-CDG patients show an increased risk for thrombosis, which might be in part due to spontaneous platelet aggregations as previously described. A potential hypoglycosylation of platelet proteins in these patients might explain this increased reactivity, as removal of sialic acid from platelets, particularly of GPIbα, leads to enhance platelet aggregation and clearance from the circulation. This study is the first one that has evaluated the glycosylation status of platelet proteins in 6 PMM2-CDG patients using different approaches including immunoblot, RCA120 lectin binding to platelets and expression of different membrane platelet N-glycoproteins by flow cytometry, as well as by platelet N-glycoproteome analysis. RCA120 lectin binding to the platelet membrane of PMM2-CDG patients showed evidence for decreased sialic acid content. However, immunoblot and flow cytometric analysis of different platelet N-glycoproteins, together with the more sensitive 2D-DIGE analysis, suggest that platelet N-glycoproteins, including GPIbα, seem to be neither quantitatively nor qualitatively significantly affected. The increased binding of RCA120 lectin could be explained by the abnormal glycosylation of hepatic proteins being attached to the platelets. CONCLUSIONS This is the first study that has evaluated the platelet N-glycoproteome. Our findings suggest that platelet proteins are not significantly affected in PMM2-CDG patients. Further studies are still warranted to unravel the mechanism(s) that increase(s) the risk of thrombosis in these patients.

High levels of latent antithrombin in plasma from patients with antithrombin deficiency

Antithrombin is an anticoagulant serpin that efficiently inhibits multiple procoagulant proteases. The cost for the structural flexibility required for this function is the vulnerability to mutations that impact its folding pathway. Most conformational mutations identified in serpins cause polymerisation. Only three mutations in SERPINC1 affecting two residues have been found to favour transformation to the latent conformation of antithrombin, another hyperstable non-anticoagulant form with strong antiangiogenic activity that constitutes 3 % of plasma antithrombin in healthy subjects. The analysis of latent antithrombin in 141 unrelated patients with antithrombin deficiency carrying 89 different SERPINC1 mutations identified four cases with higher levels than that of controls: p.Pro439Thr, p.Pro461Ser, p.Met283Val, and p.His401Tyr, the last also with circulating polymers. Heating of plasma at 42ºC exacerbated the transformation to the latent conformation in p.Pro439Thr and p.Pro461Ser. The conformational effect of p.Met283Val, the mutation associated with the highest levels of latent antithrombin detected in four members of a family, was verified in a recombinant model. Antithrombin deficiency in these cases should be classified as pleiotropic based on the impaired reactivity and low heparin affinity of the variant. Despite high levels of latent antithrombin (up to 80 µg/ml in p.Met283Val carriers), no vascular defects were described in carriers of these mutations. In conclusion, our study identifies new residues involved in the structural stability of antithrombin (and potentially of all serpins). High levels of endogenous latent antithrombin seem to play a minor antiangiogenic effect. Finally, pleiotropic deficiencies may be caused by mutations inducing transformation to the latent conformation.

A new method to quantify β-antithrombin glycoform in plasma reveals increased levels during the acute stroke event.

INTRODUCTION β-antithrombin, the minor antithrombin glycoform in plasma, is probably the major thrombin inhibitor in vivo because of its high heparin affinity. The levels and variability of this glycoform in general population and its relevance in thromboembolic diseases is unknown since there is no specific method to measure this glycoform in clinical samples. METHODS Plasma and recombinant α- and β-antithrombins were purified by heparin affinity chromatography. An anti-FXa chromogenic method in presence of pentassacharide was used with two NaCl concentrations (15mM and 1.1M). This method was applied to plasma samples from 97 healthy subjects and 117 consecutive patients with ischemic cerebrovascular disease during the acute event and one year later. SERPINC1 sequencing was done in cases with antithrombin deficiency. RESULTS High salt concentrations specifically restricted the pentassacharide-induced activation of antithrombin to the β glycoform. β-antithrombin displayed a normal distribution in the general population (89.5%-103.5%), with no significant variations according to age or sex. In patients, whole antithrombin values remained within the normal range. Only five cases had antithrombin deficiency during the thrombotic event, one carrying the L99F mutation in SERPINC1. Interestingly, both β-antithrombin and the β/whole antithrombin ratio were significantly higher in patients during the acute event but normalized after one year. CONCLUSIONS We have developed a rapid, simple, sensitive and specific method to quantify β-antithrombin activity using 1μL of plasma. β-antithrombin significantly increases in patients with ischemic cerebrovascular disease during the acute event, probably by its release from the vasculature.

High incidence of FXI deficiency in a Spanish town caused by 11 different mutations and the first duplication of F11: Results from the Yecla study

Factor XI (FXI) deficiency is a rare disorder with molecular heterogeneity in Caucasians but relatively frequent and molecularly homogeneous in certain populations.

Compound heterozygosity involving Antithrombin Cambridge II (p.Ala416Ser) in antithrombin deficiency

Compound heterozygosity involving Antithrombin Cambridge II (p.Ala416Ser) in antithrombin deficiency -